Layered Oxygen-Deficient Double Perovskites as Promising Cathode Materials for Solid Oxide Fuel Cells

Development of new functional materials with improved characteristics for solid oxide fuel cells (SOFCs) and solid oxide electrolysis cells (SOECs) is one of the most important tasks of modern materials science. High electrocatalytic activity in oxygen reduction reactions (ORR), chemical and thermomechanical compatibility with solid electrolytes, as well as stability at elevated temperatures are the most important requirements for cathode materials utilized in SOFCs. Layered oxygen-deficient double perovskites possess the complex of the above-mentioned properties, being one of the most promising cathode materials operating at intermediate temperatures. The present review summarizes the data available in the literature concerning crystal structure, thermal, electrotransport-related, and other functional properties (including electrochemical performance in ORR) of these materials. The main emphasis is placed on the state-of-art approaches to improving the functional characteristics of these complex oxides.

Despite essential progress, which recently has been achieved in the development of individual SOFCs materials (electrolytes, anodes, cathodes, collectors, and sealants) [3,[6][7][8][9][10][12][13][14][15][16][17][18][19][20] and the production and testing of SOFCs [1,2,7,[21][22][23], some urgent challenges still exist. One of the most important of these challenges is the search for, development of, and study of new electrode materials, which possess high stability, thermal and chemical compatibility, and improved electrochemical performance towards cathode and electrode reactions occurring in SOFCs. Regarding anodes (fuel electrodes), this problem was partially solved by the development of a new class of anode materials based on double perovskite molybdates SrMMoO 6 (M = Ni, Mg, and Fe) and their derivatives, including cermets [4,24,25]. Discussing the cathodes (oxygen or air electrodes), one of the most interesting and promising materials for IT-SOFCs are the layered oxygen-deficient double perovskites, LnBaM 2 O 6-δ (Ln-rare-earth element; M-3d-metal), which have been intensively studied with this aim for last two decades [4,[8][9][10]. Due to the high tolerance of perovskite structure, these complex oxides can be formed at different combinations of their constituents, demonstrating outstanding thermal, electrotransport-related, magnetic, electrochemical, and other properties. As a result, these double perovskites can be used as working elements of chemical gas sensors, high-temperature thermoelectrics, cathode materials of IT-SOFCs, etc. [26].
The present article provides an overview of peculiarities of the crystal structure, physicochemical properties, and electrochemical performance of layered oxygen-deficient perovskites as cathode materials of SOFCs, as well as ways and methods of improving the functional characteristics of these materials.

Cathode Materials for IT-SOFCs: Past, Present, and Future
An ideal cathode material for a SOFC must possess [27][28][29][30][31][32][33]: (a) high electronic (n-or p-type) conductivity (in an oxidizing atmosphere, preferably, more than 10 2 S cm −1 ); (b) thermal and chemical compatibility with solid electrolytes and interconnectors; (c) enough large porosity to provide fast diffusion of gaseous oxygen through a cathode to a triple-phase cathode-solid electrolyte-gas phase interface; (d) high stability in an oxidizing atmosphere; (e) high catalytic activity in an oxygen reduction reaction (ORR); and (f) low cost.
Typical cathode materials utilized in SOFCs are perovskites (ABO 3 ) of light rare-earth elements (REE), 3d-metals (usually, Mn, Fe, Co, and Ni), and their solid solutions and composites [4,[6][7][8][9][10]27,[34][35][36][37][38][39]. Among all cathode materials, Co-based perovskites and their derivatives received enormous research interest and played an integral role in the development and commercialization of IT-SOFCs [14,21,26,39]. Figure 1 shows the crystal structures of perovskites and other complex oxides possessing mixed ionic-electronic conductivity (MIEC), which have been used as cathode materials for SOFCs operating in different temperature intervals. A common strategy for tuning their functional properties is the partial heterovalent substitution of A-or/and B-site cations in their structure, mostly to enhance electrical conductivity and to lower the value of the thermal expansion coefficient (TEC). To decrease the electrode polarization losses at reduced operating temperatures, the addition of noble metals (Pd, Ag, and Pt) to the cathode material is used as well [27]. To increase the compatibility of these compounds with the solid electrolyte, they are often used in the form of composites.
During the investigation of ABO 3 perovskite solid solutions, a new class of oxide materials (named layered oxygen-deficient double perovskites (LODPs)), LnBa(M',M") 2 O 6-δ (Ln is REE; M', M" are 3d-metals) (cation-ordered phases), was purposefully designed. Their electrochemical performance is reported to be better than that of the parent perovskites. Therefore, these phases are currently considered as being very promising cathode Another group of cathode materials includes complex oxides with so-called Ruddlesden-Popper (RP) phases (layered oxides) with a general formula of A n+1 B n O 3n+1 . These compounds, for example, Ln 2 NiO 4+δ (Ln = La, Pr, Nd), and their solid solutions possess high diffusivity of interstitial oxygen ions, comparatively low TEC values, and high enough electrical conductivity, which also makes them promising for SOFCs applications [6,8,10,27,40]. Other RP phases, such as (Sr,La) 3 (Fe,Co) 2 O 7-x (n = 2) and (La,Sr) 4 (Fe,Co) 3 O 10−x (n = 3) showed good electrocatalytic activity in ORR in single cell measurements [6].
Recently, it has been shown that effective cathodes for proton-conducting SOFCs operating at low and intermediate temperatures are Ba(Ce,Zr)O 3 -based solid solutions doped with transition elements in high concentration. These phases demonstrate excellent chemical compatibility with typical proton-conducting solid electrolytes due to the similarity of their compositions [43,44]. These compounds belong to the triple-conducting oxides (TCOs) [45][46][47], in which transport species are simultaneously protons, oxygen ions, and electrons (holes). The advantage of TCOs as cathode materials for proton-conducting SOFCs is that both protons from the solid electrolyte and oxygen species adsorbed from the air may migrate through the bulk and over the surface of the cathode, which extends the reaction area over the whole electrode. We should note that LODPs, such as LnBa 0.5 Sr 0.5 Co 1.5 Fe 0.5 O 5+δ (Ln = Pr, Nd), when used as cathodes for proton-conducting SOFCs, also belong to the class of TCOs [9,44]. According to [48], triple conductivity in LODPs can appear due to the formation of impurity phases, which should be taken into account for the development of new TCOs.
Very interesting and promising materials for use in SOFCs are high-entropy ceramics (HECs, Figure 2), which are solid solutions of inorganic compounds (including metal oxides) with one or more Wyckoff site shared by equal or near-equal atomic ratios of five (or occasionally four) constituting elements [49,50]. The so-called compositionally complex ceramics (CCCs) include, besides HECs, medium-entropy and/or non-equimolar compositions [51]. It has been shown recently that medium-and high-entropy perovskite oxides, such as Sr(Fe α Ti β Co γ Mn ζ )O 3-δ [52], (La,Sr)(Co,Cr,Fe,Mn,Ni)O 3-δ [53,54], and (La,Pr,Nd,Sm,Ba,Sr)(Co,Fe,Ni,Cu)O 3-δ [55] demonstrate lower TECs with a lack of visible contribution from the chemical expansion effect and a more stable and much lower polarization resistance compared with the conventional cathode materials. These peculiarities make such materials very attractive for electrochemical applications.
Materials 2022, 15,141 (or occasionally four) constituting elements [49,50]. The so-called compositiona plex ceramics (CCCs) include, besides HECs, medium-entropy and/or non-e compositions [51]. It has been shown recently that medium-and high-entropy p oxides, such as Sr(FeαTiβCoγMnζ)O3-δ [52], (La,Sr)(Co,Cr,Fe,Mn,Ni)O3-δ [53, (La,Pr,Nd,Sm,Ba,Sr)(Co,Fe,Ni,Cu)O3-δ [55] demonstrate lower TECs with a lack contribution from the chemical expansion effect and a more stable and much l larization resistance compared with the conventional cathode materials. These p ties make such materials very attractive for electrochemical applications. Fields of using high-entropy materials for energy conversion and storage purp produced from [49] with permission from the Royal Society of Chemistry).

Crystal Structure, Phase Transitions, and Physicochemical and Functional P ties of Layered Oxygen-Deficient Double Perovskites
The crystal structure of LnBa(M',M")2O6-δ LODPs, consisting of alternating (-(M',M")O2-) and LnO1-δ layers, is formed due to the ordering of oxygen vacan and Ba atoms in the structure of oxygen deficient LnM'(M")O3-δ perovskites acco Equation (1): 2Ln0.5Ba0.5CoO3-δ (Pm3m) →LnBaCo2O6-δ (P4/mmm or Pmmm) A structural phase transition occurs at such an arrangement: cubic p structure (Pm3m) transforms into a tetragonal (P4/mmm) or an orthorhombic structure ( Figure 3). A different character of oxygen-vacancy ordering, as well a dering of M' and M" ions, may result in the fact that LODPs crystallize in oth groups (SGs), such as P1, P2, or Ammm [26]; nevertheless, P4/mmm or Pmmm are typical ones. Fields of using high-entropy materials for energy conversion and storage purposes (Reproduced from [49] with permission from the Royal Society of Chemistry).

Crystal Structure, Phase Transitions, and Physicochemical and Functional Properties of Layered Oxygen-Deficient Double Perovskites
The crystal structure of LnBa(M',M") 2 O 6-δ LODPs, consisting of alternating (-BaO-), (-(M',M")O 2 -) and LnO 1-δ layers, is formed due to the ordering of oxygen vacancies, Ln, and Ba atoms in the structure of oxygen deficient LnM'(M")O 3-δ perovskites according to Equation (1): A structural phase transition occurs at such an arrangement: cubic perovskite structure (Pm3m) transforms into a tetragonal (P4/mmm) or an orthorhombic (Pmmm) structure ( Figure 3). A different character of oxygen-vacancy ordering, as well as the ordering of M' and M" ions, may result in the fact that LODPs crystallize in other space groups (SGs), such as P1, P2, or Ammm [26]; nevertheless, P4/mmm or Pmmm are the most typical ones. This transition usually occurs at high temperatures and low oxygen partial pressures and may proceed through the formation of an intermediate product with a complex domain structure, which has a strong affinity with oxygen and may exchange it with an atmosphere at relatively low temperatures (ca. 340 K) [57].
Oxygen content variation in LODPs results in a change in their structure, which takes place at different temperatures depending on the cationic composition and oxygen partial pressure. For example, GdBaCo2-xFexO6-δ (0 ≤ x ≤ 0.4) perovskites undergo a Pmmm-P4/mmm phase transition at approximately730-760 K [58]. Layered cobaltites of REE and barium undergo the dielectric-metal transition, in which their electrical conductivity increases by several orders of magnitude. This is caused by a change in the spin state of the cobalt ions [26,59]. At high temperatures, these phases are paramagnetic, but at cooling LODPs become antiferro-, ferri-, or ferromagnetic [26,[60][61][62] due to a different type of ordering of magnetic moments of the transition metal ions in their structure.
Double perovskites LnBaCo2O5+δ (Ln = Eu, Gd, and Sm) containing weakly-bonded oxygen (δ) and cobalt ions in different oxidation states (Co 2+ , Co 3+ , Co 4+ ) demonstrate certain photocatalytic activity during the degradation of Congo Red, which indicates that they may be promising photocatalysts for the oxidation (degradation) of organic substances [74].
To be used in high-temperature devices, such as SOFCs, solid oxide electrolysis cells (SOECs), TEGs, and other applied directions, LODPs must possess a good thermomechanical and chemical compatibility with other components of these devices [75]. The first condition of thermomechanical compatibility is the similarity of their TEC values with those of the typical solid electrolytes used in SOFCs. The TEC values for some typical LODPs are set outin Table 1. As can be seen, for the layered perovskites with only Co atoms in B-site, the TEC values vary within ca. (17−24) × 10 −6 K −1 ; the measured TECs are This transition usually occurs at high temperatures and low oxygen partial pressures and may proceed through the formation of an intermediate product with a complex domain structure, which has a strong affinity with oxygen and may exchange it with an atmosphere at relatively low temperatures (ca. 340 K) [57].
Oxygen content variation in LODPs results in a change in their structure, which takes place at different temperatures depending on the cationic composition and oxygen partial pressure. For example, GdBaCo 2-x Fe x O 6-δ (0 ≤ x ≤ 0.4) perovskites undergo a Pmmm-P4/mmm phase transition at approximately 730-760 K [58]. Layered cobaltites of REE and barium undergo the dielectric-metal transition, in which their electrical conductivity increases by several orders of magnitude. This is caused by a change in the spin state of the cobalt ions [26,59]. At high temperatures, these phases are paramagnetic, but at cooling LODPs become antiferro-, ferri-, or ferromagnetic [26,[60][61][62] due to a different type of ordering of magnetic moments of the transition metal ions in their structure.
Double perovskites LnBaCo 2 O 5+δ (Ln = Eu, Gd, and Sm) containing weakly-bonded oxygen (δ) and cobalt ions in different oxidation states (Co 2+ , Co 3+ , Co 4+ ) demonstrate certain photocatalytic activity during the degradation of Congo Red, which indicates that they may be promising photocatalysts for the oxidation (degradation) of organic substances [74].
To be used in high-temperature devices, such as SOFCs, solid oxide electrolysis cells (SOECs), TEGs, and other applied directions, LODPs must possess a good thermomechanical and chemical compatibility with other components of these devices [75]. The first condition of thermomechanical compatibility is the similarity of their TEC values with those of the typical solid electrolytes used in SOFCs. The TEC values for some typical LODPs are set out in Table 1. As can be seen, for the layered perovskites with only Co  The TEC values of layered oxygen-deficient double cobaltites decline when the REEs' ionic radii decrease, as well as when a partial substitution of cobalt with iron (at small doping levels) or copper occurs ( Table 1). Both of these strategies are effective in improving the thermomechanical properties of LODPs. Molecular dynamics simulations have shown [76], that variations in the cationic composition or/and oxygen nonstoichiometry of layered oxygen-deficient double cobaltites is the other effective way to reduce the TEC values of these materials.
The TEC values of LODPs sharply increase at high temperatures (above ca. 500-700 K) due to the beginning of the evolution of weakly-bonded oxygen from their crystal structures into the environment. Therefore, the expansion of these phases at high temperatures is determined by both thermal and chemical factors [26,58,62,75].
The chemical expansion coefficient (CEC) values of some LODPs are provided in Table 2. As can be seen, these values vary within 0.5-2.6%, exhibiting a strong anisotropy; simultaneous chemical expansion along the a-axis (in the ab-plane) and chemical contraction along the c-axis (out-of-plane) take place during the evolution of weakly-bonded oxygen. According to [58,77], the former occurs due to an increase inthe average radii of cobalt ions due to their reduction, but the latter occurs due to the change in the coordination environment of REE and cobalt ions. PrBaCuFeO 5+δ (P4/mmm) 12.0 volume [80] A serious drawback of layered cobaltites is their degradation in CO 2 -containing atmospheres. For example, Zhu et al. [81] have studied the degradation features of PrBaCo 2 O 5+δ in CO 2 -containing atmospheres. They found a considerable decrease in the electrochemical activity of PrBaCo 2 O 5+δ electrodes due to the formation of insulating BaCO 3 particles at the PrBaCo 2 O 5+δ surface.
On the other side, efficient cathodes of SOFCs should provide a large oxygen exchange rate between the atmosphere and the surface of the cathode and enough high oxygen mobility. Therefore, both bulk and surface chemistry in the oxygen exchange kinetics of MIEC layered perovskites are very important. It was found [82] that the surfaces of PrBaCo 2 O 5+δ and GdBaCo 2 O 5+δ LODPs can significantly change in their local chemical composition and can exchange by oxygen with the atmosphere even at ambient temperature.
Perry and Ishihara [83] summarized the main directions of improving the efficiency and durability of oxygen electrodes (including those based on LODPs) in SOFCs. Concerning the bulk chemistry, the areas of "electro-chemo-mechanics" are (1) the enhancement in transport and surface reactivity through the strain-state tailoring (mechano-electrical and mechano-electrochemical coupling) and (2) the mitigation of deleterious chemical expansion during operation, induced by stoichiometry changes (chemo-mechanical coupling). Regarding the surface chemistry and oxygen surface exchange kinetics, the main areas of interest are (1) clarifying the rate-limiting steps and mechanisms of oxygen incorporation/excorporation with atomistic insight; (2) exploiting the unique properties of hetero-interfaces, grain boundaries, and other large surface defects; (3) identifying the optimal composition for the outermost atomic monolayers; and (4) studying how to control the outermost chemistry in operating conditions via bulk and surface chemical tailoring.
Oxygen mobility in materials used in SOFCs and catalytic membranes was comparatively discussed in detail in [84]. The results of the investigation of chemical compatibility between different oxide electrodes and solid electrolytes in SOFCs are provided in [85]. Concerning LODPs, cathode materials such as with Fe, Cu, and Nb at the B-site of RBaCo 2 O 5+δ (R = Pr and Y) can effectively improve chemical compatibility between the LODP cathodes and SDC or GDC solid electrolytes. Figure 4 shows the XRD results for YBaCoCuO 5+δ (YBCC) and YBaCo 2/3 Fe 2/3 Cu 2/3 O 5+δ (YBCFC), which were calcined at 1223 K for 10 h in air mixtures with different solid electrolytes (SDC, GDC, and LSCM). No impurities or shifts of diffraction peaks were observed for compositions containing YBCC (Figure 4a), indicating that this compound is chemically compatible with the studied electrolytes. On the contrary, small amounts of Sm 2 CuO 4 and Gd 2 CuO 4 impurity phases in the YBCFC-SDC and YBCFC-GDC mixtures were observed (Figure 4b), showing that the YBCFC material is incompatible with SDC and GDC electrolytes. However, the absence of impurity phases in the YBCFC-LSCM mixture indicates that YBCFC presents good chemical compatibility with LSCM solid electrolytes below 1223 K. Ba(Zr,Y)O3-δ (BZY) or Ba(Zr,Y,Yb)O3-δ (BZYYb) proton conductors were not observed. However, GdBaCo2O5+δ reacts with YSZ at 973 K with the formation of BaZrO3. Doping with Fe, Cu, and Nb at the B-site of RBaCo2O5+δ (R = Pr and Y) can effectively improve chemical compatibility between the LODP cathodes and SDC or GDC solid electrolytes. Figure 4 shows the XRD results for YBaCoCuO5+δ (YBCC) and YBaCo2/3Fe2/3Cu2/3O5+δ (YBCFC), which were calcined at 1223 K for 10 h in air mixtures with different solid electrolytes (SDC, GDC, and LSCM). No impurities or shifts of diffraction peaks were observed for compositions containing YBCC (Figure 4a), indicating that this compound is chemically compatible with the studied electrolytes. On the contrary, small amounts of Sm2CuO4 and Gd2CuO4 impurity phases in the YBCFC-SDC and YBCFC-GDC mixtures were observed (Figure 4b), showing that the YBCFC material is incompatible with SDC and GDC electrolytes. However, the absence of impurity phases in the YBCFC-LSCM mixture indicates that YBCFC presents good chemical compatibility with LSCM solid electrolytes below 1223 K. Tsvetkov et al. [87] found that PrBaCo2O5+δ and SDC experienced the interdiffusion of Pr and Sm at 1273 K; the formation of BaCeO3 had high electrical resistivity. Diffusion of praseodymium into the electrolyte resulted in an increase in its electronic conductivity, which led to adecrease in the open-circuit voltage and even the short circuit of the cell [88]. The formation of the BaCeO3 phase also increased the ohmic and polarization resistance of the components of the electrochemical cell.
The NdBaFe1.9Mn0.1O5+δ cathode material showed good chemical compatibility with the BaZr0.1Ce0.7Y0.2O3-δ (BZCY) electrolyte at a temperature of 1173 K [89]. In [90], it was shown that Sr2(Co,Nb)FeO5+δ double perovskites do not react with La0.9Sr0.1Ga0.8Mg0.2O3 (LSGM) at 1273 K in air, indicating the good chemical compatibility of these compounds. Tsvetkov et al. [87] found that PrBaCo 2 O 5+δ and SDC experienced the interdiffusion of Pr and Sm at 1273 K; the formation of BaCeO 3 had high electrical resistivity. Diffusion of praseodymium into the electrolyte resulted in an increase in its electronic conductivity, which led to adecrease in the open-circuit voltage and even the short circuit of the cell [88]. The formation of the BaCeO 3 phase also increased the ohmic and polarization resistance of the components of the electrochemical cell.

Layered Cobaltites of REEs and Barium
The main advantages of layered oxygen-deficient cobaltites as cathodes for SOFCs are their superior electronic and ionic conductivity, as well as their higher electrocatalytic activity towards the ORR, especially in the IT-temperature range [8][9][10]34,35,40]. Table 3 summarizes the electrochemical performance of REE-barium layered cobaltites. Table 3. Performance (ASR: area specific resistance, MPD: maximal power density) of SOFCs based on REE-barium layered double cobaltites.

Cathode
Electrolyte ASR, Ω cm 2 (T, K) MPD, mW cm −2 (T, K) Refs. According to this table, layered cobaltites exhibit good electrochemical activity with the lowest ASR value of 0.0086 Ω cm 2 at 1073 K reached for the LaBaCo 2 O 5+δ cathode. This is much lower than values taken for commonly used LODPs. The ASR value for the NdBaCo 2 O 5+δ cathode is 0.08 Ω cm 2 at 973 K, under a cathodic applied voltage of −0.1 V [96]. The activation energy of the interface conductivity of these materials varied within~110 kJ mol -1 and 160 kJ mol -1 , decreasing with an increase in the applied voltage (E), since the diffusion process was more easily affected by the increase in E than the charge transfer process.

Layered Cobaltites of REEs and Barium
The main advantages of layered oxygen-deficient cobaltites as cathodes for SOFCs are their superior electronic and ionic conductivity, as well as their higher electrocatalytic activity towards the ORR, especially in the IT-temperature range [8][9][10]34,35,40]. Table 3 summarizes the electrochemical performance of REE-barium layered cobaltites. According to this table, layered cobaltites exhibit good electrochemical activity with the lowest ASR value of 0.0086 Ω cm 2 at 1073 K reached for the LaBaCo2O5+δ cathode. This is much lower than values taken for commonly used LODPs. The ASR value for the NdBaCo2O5+δ cathode is 0.08 Ω cm 2 at 973 K, under a cathodic applied voltage of −0.1 V [96]. The activation energy of the interface conductivity of these materials varied within ~110 kJ mol -1 and 160 kJ mol -1 , decreasing with an increase in the applied voltage (E), since the diffusion process was more easily affected by the increase in E than the charge transfer process.
The electrocatalytic activity and stability of LnBaCo 2 O 5+δ (Ln = La, Pr, Nd, Sm, Eu, and Gd) perovskites in the hydrogen evolution reaction (HER) were studied in [103]. It was found, from the DFT calculations, that LnBaCo 2 O 5+δ phases exhibit an optimal free energy combination for the H 2 O adsorption/dissociation and -OH/H* desorption, which open up the opportunity for the development of new perovskite-based energy materials.

A-Site-Deficient and A-Site-Substituted LnBaCo 2 O 5+δ Layered Perovskites
An effective way to improve functional properties of the discussed layered perovskites is through the creation of a cation deficiency in their A-sublattice (both in REE and barium positions) and partial isovalent substitution of barium with smaller alkaline-earth elements (AEEs), such as strontium or calcium. Table 4 summarizes some results obtained for SOFCs based on such double perovskites.
Single-phase materials are formed at a relatively small deficiency of REE (8 mol.% for Pr [104], 5-10 mol.% for Sm [105,106]). The formation of REE-vacancies in the Ln 1−x BaCo 2 O 5+δ phases leads to an increase in their lattice constants and decreases their oxygen content. This results in a decrease of their electrical conductivity, and improvement of their electrochemical performance (particularly, to the essential lowering of ASR and increasing of PD [105][106][107]), at least at a low REE deficiency level (approximately5 mol.%).
The addition of potassium results in a higher cation deficiency in the PrBa 1−x Co 2 O 5+δ perovskites, improving bulk oxygen transport [114]. However, the cobalt content at the surface of these samples was found to have decreased as well, causing the deterioration of their electrochemical performance towards the surface oxygen exchange.
Inter-substitution of praseodymium by barium in Pr 1+x Ba 1−x Co 2 O 6-δ leads to the formation of double-phase composites comprising orthorhombic PrBaCo 2 O 6-δ (SG Pmmm) and PrCoO 3 (SG Pnma) for x = 0.2 and 0.8 [115]. The triple-phase boundary reaction suggests the formation of Co(OH) 3 along with the H 2 gas evolution during the electrochemical dissolution of these composite electrodes with H 2 O inreaction (2).
The sample with x = 0.6 showed a higher ORR rate with more intense H 2 gas evolution compared with the others. Lu et al. [116], using the conventional solid-state reactions method, synthesized an A-site deficient double perovskite PrBa 0.94 Co 2 O 5+δ (A-PBC) and then created nanorods of simple perovskite (PrCoO 3 ) on the surface of its particles via an in situ exsolution process, which resulted in the formation of a heterostructured simple perovskite nanorod-decorated double perovskite cathode (SPN-A-PBC). High electrocatalytic activity of the SPN-A-PBC cathode toward ORR was found, achieving apolarization resistance of about 0.025 Ω cm 2 at 973 K in air. The anode-supported single cell with the SPN-A-PBC cathode reached a power density of 1.1 W cm −2 at 973 K and a superior steady operation over 120 h at a loading voltage of 0.6 V ( Figure 6). This electrode also exhibited a good tolerance to CO 2 ; when tested in air with 6 vol.% CO 2 at 973K, it maintained a stable polarization resistance of about 0.078 Ω cm 2 .  A partial substitution of barium withsmaller strontium or/and calcium in LnBaCo2O5+δ leads to the expected decrease of lattice constants and TEC values [117][118][119][120]124] and an increase in the electrical conductivity [118,123,124] and the electrochemical performance of the corresponding materials [117][118][119][120][121][122][123][124].
In [118], a co-doping strategy of both Pr and Ba by Ca in layered PrBaCo2O5+δ cobaltite for improving its properties was used. It was shown that this strategy makes it possible to increase electrical conductivity and thermal stability of the samples as well as to A partial substitution of barium with smaller strontium or/and calcium in LnBaCo 2 O 5+δ leads to the expected decrease of lattice constants and TEC values [117][118][119][120]124] and an increase in the electrical conductivity [118,123,124] and the electrochemical performance of the corresponding materials [117][118][119][120][121][122][123][124].
In [118], a co-doping strategy of both Pr and Ba by Ca in layered PrBaCo 2 O 5+δ cobaltite for improving its properties was used. It was shown that this strategy makes it possible to increase electrical conductivity and thermal stability of the samples as well as to reduce ASR values and enlarge MPD ( Table 4). The NdBa 0.5 Sr 0.25 Ca 0.25 Co 2 O 5+δ cathode demonstrated a very low ASR value of 0.062 Ω cm 2 at 1073 K and a maximum output power density of 812 mW cm −2 at 1073 K (Figure 7). This measurement was much higher than for NdBa 0.5 Sr 0.5 Co 2 O 5+δ , proving the effectiveness of the co-doping strategy.  Through the electrical conductivity relaxation (ECR) test, the values of chemical bulk diffusion coefficient (Dchem) of oxygen in SmBa0.6Sr0.4Co2O5+δ were measured from 1.63 × 10 −6 cm 2 s −1 at 773 K to 1.41 × 10 −5 cm 2 s −1 at 973 K [126]. The temperature dependence of Dchem in a temperature range of 773-973 K is described by Equation (3) The oxygen transport properties of SmBa0.5Sr0.5Co2O5+δ as a potential cathode material for IT-SOFCs were investigated in [127]. The Dchem values for SmBa0.5Sr0.5Co2O5+δ were equal to 2.6 × 10 −6 , 9.1 × 10 −6 , and 1.8 × 10 −5 cm 2 s −1 at 773, 873, and 973 K, respectively. The activation energy of Dchem within 773-973 K was ~58 kJ mol −1 . Oxygen permeation flux for the SmBa0.5Sr0.5Co2O5+δ membrane with a thickness of 1.00 mm increased from 0.143 mL min −1 cm −2 at 773 K to 0.406 mL min −1 cm −2 at 1073 K under synthetic air at a flow rate of 50 mL min −1 and helium at a rate of 25 mL min −1 . The activation energies of oxygen permeation for a high-temperature region (973-1073 K) and a low-temperature region (773-923 K) were equal to ~24 and 7 kJ mol −1 , respectively, suggesting that the oxygen diffusion in the high-temperature and low-temperature ranges occurred via surface exchange and bulk diffusion mechanisms, respectively.

B-Site Deficient and B-Site Substituted LnBaCo2O5+δ Layered Perovskites
Co-deficient PrBaCo2−xO6-δ (0 ≤ x ≤ 0.1) perovskites were prepared and investigated in [128]. It was found that increasing the concentration of the vacancies in the Co-sublattice ledto an increase in lattice constants and oxygen nonstoichiometry (δ), additionally, the electrical conductivity decreased and electrochemical performance of PrBaCo2-xO6-δ cathodes improved. The minimum value of ASR and the maximum value of MPD were found for PrBaCo1.94O6-δ, they were 0.059 Ω cm 2 at 973 K and 889 mW cm −2 at 923 K, respectively. This was 16% lower and higher, respectively, than for the cation-stoichiometric PrBaCo2O6-δ phase. The thermal stability of the samples did not change Through the electrical conductivity relaxation (ECR) test, the values of chemical bulk diffusion coefficient (D chem ) of oxygen in SmBa 0.6 Sr 0.4 Co 2 O 5+δ were measured from 1.63 × 10 −6 cm 2 s −1 at 773 K to 1.41 × 10 −5 cm 2 s −1 at 973 K [126]. The temperature dependence of D chem in a temperature range of 773-973 K is described by Equation (3) The oxygen transport properties of SmBa 0.5 Sr 0.5 Co 2 O 5+δ as a potential cathode material for IT-SOFCs were investigated in [127]. The D chem values for SmBa 0.5 Sr 0.5 Co 2 O 5+δ were equal to 2.6 × 10 −6 , 9.1 × 10 −6 , and 1.8 × 10 −5 cm 2 s −1 at 773, 873, and 973 K, respectively. The activation energy of D chem within 773-973 K was~58 kJ mol −1 . Oxygen permeation flux for the SmBa 0.5 Sr 0.5 Co 2 O 5+δ membrane with a thickness of 1.00 mm increased from 0.143 mL min −1 cm −2 at 773 K to 0.406 mL min −1 cm −2 at 1073 K under synthetic air at a flow rate of 50 mL min −1 and helium at a rate of 25 mL min −1 . The activation energies of oxygen permeation for a high-temperature region (973-1073 K) and a low-temperature region (773-923 K) were equal to~24 and 7 kJ mol −1 , respectively, suggesting that the oxygen diffusion in the high-temperature and low-temperature ranges occurred via surface exchange and bulk diffusion mechanisms, respectively.

B-Site Deficient and B-Site Substituted LnBaCo 2 O 5+δ Layered Perovskites
Co-deficient PrBaCo 2−x O 6-δ (0 ≤ x ≤ 0.1) perovskites were prepared and investigated in [128]. It was found that increasing the concentration of the vacancies in the Co-sublattice ledto an increase in lattice constants and oxygen nonstoichiometry (δ), additionally, the electrical conductivity decreased and electrochemical performance of PrBaCo 2-x O 6-δ cath-odes improved. The minimum value of ASR and the maximum value of MPD were found for PrBaCo 1.94 O 6-δ , they were 0.059 Ω cm 2 at 973 K and 889 mW cm −2 at 923 K, respectively. This was 16% lower and higher, respectively, than for the cation-stoichiometric PrBaCo 2 O 6-δ phase. The thermal stability of the samples did not change due to the formation of Co-deficiency. Table 5 shows some typical results concerning the electrochemical performance of SOFCs with a B-site substituted REE-barium layered cobaltites as cathodes.
In [136], it was found that a partial substitution of cobalt withhigh-valence tantalum in PrBa 0.94 Co 2 O 5+δ stabilizes the A-site-ordered layered perovskite structure, slightly increases TEC and electrical conductivity of the samples, and improves catalytic activity towards ORR. The optimal composition, PrBa 0.94 Co 1.96 Ta 0.04 O 5+δ , exhibits the lowest polarization resistance (0.020 Ω cm 2 at 973 K) and the highest power density of 1050 mW cm −2 at 973 K and is operated steadily at a loading voltage of 0.6 V over 100 h at 923 K. The PrBa 0.94 Co 1.96 Ta 0.04 O 5+δ cathode showed excellent tolerance to CO 2 , as evidenced by its durable polarization resistance of 0.061 Ω cm 2 at 973 K in air with 10 vol.% of CO 2 . A partial substitution of cobalt by high-valence molybdenum ions in PrBaCo 2−x Mo x O 5+δ almost did not affect the crystal structure of the parent oxide but decreased its TEC and electrical conductivity values [137]. The polarization resistance of the PrBaCo 1.97 Mo 0.03 O 5+δ (PBCM-0.03) cathode was 0.067 Ω cm 2 at 973 K, which was slightly higher than for the pristine PrBaCo 2 O 5+δ cathode (PBCO) (0.060 Ω cm 2 at 973 K). The maximum power density of the single cells containing thePBCM-0.03 and PBCO cathodes at 973 K attained 343 and 339 mW cm −2 , respectively. It was also found in [137] that trace amounts of high-valence Mo-doping in the PrBaCo 2 O 5+δ cathode improved its electrochemical stability. So, generally, the results obtained in [137] showed that PrBaCo 2−x Mn x O 5+δ solid solutions are attractive for applications as SOFCs cathodes.
The isovalent Co-by-Mn substitution in LODPs was studied in [138][139][140][141]. It was found that the TEC and electrical conductivity of SmSrCo 2−x Mn x O 5+δ (0 ≤ x ≤ 1) perovskites decreased with increasing x. The electrochemical performance of SmSrCo 2 O 5+δ slightly decreased after Mn-doping; however, reduced TEC and good chemical compatibility with GDC indicate that these materials may be used as SOFCs cathodes. Similar results were observed in another work [139], where GdBaCo 2-x Mn x O 5+δ (0 ≤ x ≤ 2) was formed within the whole studied composition region. Mn-doped oxides showed lower electrical conductivity and increased polarization resistance. Nevertheless, these materials exhibited an increased oxygen content (δ) and reduced TEC values. Moderate TEC values and good catalytic activity in ORR were found for the LnBaCo 2−x Mn x O 5+δ perovskites [140,141].
A suspension plasma-sprayed PrBa 0.5 Sr 0.5 Co 1.6 Fe 0.4 O 5+δ (PBSCF) cathode operating in a symmetrical cell of PBSCF|ScSZ|PBSCF (ScSZ-scandia stabilized zirconia) and a single cell of Ni-GDC|ScSZ|PBSCF showed good electrochemical performance with as low a ASR value as 0.074 Ω cm 2 and 0.012 Ω cm 2 at 873 K and 973 K, respectively, peak power densities of 370, 800, and 1350 mW cm −2 at 773 K, 873 K, and 973 K, respectively, as well as excellent long-term stability (its polarization resistance remained practically constant during isothermal dwelling at 973 K for 300 h) [154].
The addition of 20 wt.% of Bi 2 O 3 to LaBaCo 2 O 5+δ resulted in the lowest ASR value (0.020 Ω cm 2 at 1073 K in air), which was about a seventh of that of the LaBaCo 2 O 5+δ cathode in the same conditions [163]. At a current density of 0.2 A cm −2 , the cathodic overpotential of LaBaCo 2 O 5+δ +20 wt.%Bi 2 O 3 was approximately 12.6 mV at 973 K, while the corresponding value for LaBaCo 2 O 5+δ was 51.0 mV.
In [165], the EuBa 0.98 Co 2 O 5+δ +x wt.%Ce 0.9 Sm 0.1 O 1.9 (EBCO-xSDC) (0 ≤ x ≤ 40) composites were systematically studied as cathode materials for SOFCs. It was found that EBCO-xSDC materials had excellent electrocatalytic ORR activity due to the synergistic effects of the high electronic-conducting EBCO phase and ionic-conducting SDC electrolyte. The best cathode performance among the studied composites was exhibited by the EBCO-20SDC material (0.028 Ω cm 2 at 973 in air), when tested in a single-cell Ni-YSZ|YSZ|CGO|EBCO-20SDC (Figure 9). A high power density of 980 mW cm −2 at 973 K was achieved, which was approximately two times higher than that for the EBCO cathodebased fuel cell. The results of electrochemical impedance spectroscopy (EIS) showed that the charge transfer was the rate-limiting step at the cathode interface. The addition of SDC to the EBCO improved both the charge transfer reaction and the gas diffusion process due to the high oxygen-ion conductivity and large surface of the SDC electrolyte. perovskite, theTEC of which was 15.7 × 10 −6 K −1 within a temperature range of 303-1123 K. The values of the polarization resistance of NBCFC were 0.056 and 0.023 Ω cm 2 at 1073 K with the Ce0.9Gd0.1O1.9 and La0.9Sr0.1Ga0.8Mg0.2O3-δ electrolytes, respectively [160]. Co-substitution with Fe and Mn sharply decreased the TEC from 21.5·10 −6 K −1 for PrBa-Co2O5+δ to 17.8 × 10 −6 K −1 for PrBaCo2/3Fe2/3Mn1/2O5+δ (PBCFM) at a temperature range of 303-1273 K [161]. When using 300μm-thick Sm0.2Ce0.8O1.9 (SDC) as an electrolyte, the ASR and maximum power density values were equal to 0.028 Ω cm 2 and 588 mW cm −2 at 1073 K, respectively. The SDC-impregnated PBCFM composite cathode showed improved electrochemical characteristics; its ASR and peak power density were 0.23 Ω cm 2 and 621 mW cm −2 at 1073 K, respectively.
The addition of 20wt.% of Bi2O3 to LaBaCo2O5+δ resulted in the lowest ASR value (0.020 Ω cm 2 at 1073 K in air), which was about a seventh of that of the LaBaCo2O5+δ cathode in the same conditions [163]. At a current density of 0.2 A cm −2 , the cathodic overpotential of LaBaCo2O5+δ+20 wt.%Bi2O3 was approximately12.6 mV at 973 K, while the corresponding value for LaBaCo2O5+δ was 51.0 mV.
In [165], the EuBa0.98Co2O5+δ+x wt.%Ce0.9Sm0.1O1.9 (EBCO-xSDC) (0 ≤ x ≤ 40) composites were systematically studied as cathode materials for SOFCs. It was found that EB-CO-xSDC materials had excellent electrocatalytic ORR activity due to the synergistic effects of the high electronic-conducting EBCO phase and ionic-conducting SDC electrolyte. The best cathode performance among the studied composites was exhibited by the EBCO-20SDC material (0.028 Ω cm 2 at 973 in air), when tested in a single-cell Ni-YSZ|YSZ|CGO|EBCO-20SDC (Figure 9). A high power density of 980 mW cm −2 at 973 K was achieved, which was approximately two times higher than that for the EBCO cathode-based fuel cell. The results of electrochemical impedance spectroscopy (EIS) showed that the charge transfer was the rate-limiting step at the cathode interface. The addition of SDC to the EBCO improved both the charge transfer reaction and the gas diffusion process due to the high oxygen-ion conductivity and large surface of the SDC electrolyte. and (c) x=20 (adopted with permission from [165]. Copyright 2019, Elsevier).
Idrees et al. [168], using a facile and effective one-pot sol-gel method, prepared a PrBa0.92Co2O6-δ-40 wt.%Ce0.8Sm0.2O1.9 (OPCC) composite cathode material and compara- Idrees et al. [168], using a facile and effective one-pot sol-gel method, prepared a PrBa 0.92 Co 2 O 6-δ -40 wt.%Ce 0.8 Sm 0.2 O 1.9 (OPCC) composite cathode material and comparatively studied its electrochemical performance in tandem with a composite cathode with the same composition which was synthesized by means of a traditional ball-milling method (BMCC), as well as with the single-phase PrBa 0.92 Co 2 O 6-δ cathode. Among the three studied cathodes, OPCC showed the lowest ASR (0.015 Ω cm 2 at 1023 K), indicating the highest ORR catalytic activity. The OPCC-based anode-supported single cell demonstrated the highest peak power densities, with a typical value of 1011 mW cm −2 at 1023 K in contrast to 783 mW cm −2 for the BMCC-based cell and 574 mW cm -2 for the PrBa 0.92 Co 2 O 6-δ -based cell. The OPCC-based cell also showed stable performance without obvious degradation over 100 h at 973 K.
In [169], the Pr 0.95 BaCo 2 O 6-δ -xCe 0.8 Sm 0.2 O 1.9 (x = 0, 30, 40, 50) composites (PBCO-xSDC) were successfully prepared and investigated. It was found that the addition of SDC to the Pr 3+ -deficient perovskite decreased its TEC and electrical conductivity values but enhanced its catalytic activity over ORR. The best electrochemical performance was shown by the PBCO-40SDC cathode, for which ASR was 0.005 Ω cm 2 at 1023 K. An anodesupported single cell with this cathode demonstrated high peak power densities, such as 1171 mW cm −2 at 1023 K and 917 mW cm −2 at 973 K.
The GdBaFeNiO 5+δ material exhibits good chemical compatibility with the Sm 0.2 Ce 0.8 O 1.9 electrolyte at temperatures below 1273 K; its ASR value is 0.219 Ω cm 2 at 1073 K, and the maximum power density of the Ni-Sm 0.2 Ce 0.8 O 1.9 |Sm 0.2 Ce 0.8 O 1.9 |GdBaFeNiO 5+δ single cell reaches 287 mW cm −2 at 1073 K [185]. The activity and performance of the GdBaFeNiO 5+δ cathode can be improved by the impregnation of nano-sized Sm 0.2 Ce 0.8 O 1.9 particles: the polarization resistance is decreased by more than 14 times (down to 0.065 Ω cm 2 at 1073 K), and the maximum power density of the single cell increased by 1.9 times (up to 515 mW cm −2 at 1073 K).
The La 1.4 Ca 0.6 CoMnO 5+δ (LCCM) material has a monoclinic structure, high structural stability up to 1173 K, and exhibits good chemical compatibility with the La 0.9 Sr 0.1 Ga 0.8 Mg 0.2 O 3-δ (LSGM) and Sm 0.2 Ce 0.8 O 1.9 (SDC) electrolytes at temperatures of up to 1273 K. The maximum power density of a NiO-SDC|SDC|LSGM|LCCM single cell reaches 445 mW cm −2 at 1073 K [186]. The electrochemical performance, thermal expansion behavior, and stability of LCCM improve by adding appropriate amounts of SDC. The LCCM-30 wt.%SDC composite cathode shows the increased electrochemical performance: the ASR is decreased by 68% and the maximum power density is increased by 22%.  [190] A partial substitution of Ba with Ca in NdBaCoCuO 5+δ resulted in decreased TEC and oxygen content and increased the electrical conductivity in air [187]. Compared to the parent oxide, the modified sample has a greatly enhanced electrochemical performance. The ASR of NdBa 1−x Ca x CoCuO 5+δ -based symmetrical cells with a Gd 0.1 Ce 0.9 O 1.95 electrolyte at 973 K dropped from 0.062 Ω cm 2 for x = 0 to 0.038 Ω cm 2 for x = 0.3. The maximum power density for NdBa 1−x Ca x CoCuO 5+δ -based single cells at 1073 K increased from 1420 mW cm −2 for x = 0 to 1840 mW cm −2 for x = 0.3 ( Figure 10). The Y1-xBaCoCuO5+δ (x=0.00, 0.03, 0.05, 0.07, 0.10) layered perovskites with a Y 3+ -deficiency were studied as cathodes for SOFCs in work [188]. These compounds crystallize in orthorhombic syngony, and their lattice constants increase with an increasing Y 3+ deficiency. The oxygen content and electrical conductivity values of Y1−xBaCoCuO5+δ decrease as x increases. The results of EIS studies indicate that the crea-3+ Figure 10. I-V and I-P curves of NdBa 1-x Ca x CoCuO 5+δ based single cells at (a) x = 0 and (b) x = 0.3 (adopted with permission from [187]. Copyright 2018, Elsevier). The Y 1-x BaCoCuO 5+δ (x = 0.00, 0.03, 0.05, 0.07, 0.10) layered perovskites with a Y 3+ -deficiency were studied as cathodes for SOFCs in work [188]. These compounds crystallize in orthorhombic syngony, and their lattice constants increase with an increasing Y 3+ deficiency. The oxygen content and electrical conductivity values of Y 1−x BaCoCuO 5+δ decrease as x increases. The results of EIS studies indicate that the creation of a Y 3+ deficiency reduces the polarization resistance, the lowest value of which was 0.029 Ω cm 2 at 1073 K and was observed for the Y 0.93 BaCoCuO 5+δ sample. The LSGM electrolyte-supported single cell with the Y 0.93 BaCoCuO 5+δ cathode demonstrated the peak power density values of 862, 643, 426, 274, and 152 mW cm −2 at 1123, 1073, 1023, 973, and 923 K, respectively.
The electrical conductivity and thermal expansion of LnBaFe 2 O 5+δ (Ln = La, Pr, Nd, Sm, Gd, and Y)-layered ferrites decreased at smaller Ln 3+ ionic radii; for example,TEC values within 293-1173 K temperature intervals decreased from 19.4 × 10 −6 K −1 for Ln = La to 14.6 × 10 −6 K −1 for Ln = Y [192]. The lowest polarization resistance in air under an open circuit voltage was found for the SmBaFe 2 O 5+δ electrode (YSZ as the electrolyte): 0.043 Ω cm 2 at 1073 K. The single cell with this material serving as its cathode delivered the highest peak power density of 1026 mW cm −2 at 1073 K [192]. The LaBa 0.5 Sr 0.5 Fe 2 O 6-δ cathode showed a low polarization resistance of 0.152 Ω cm 2 at 1023 K and a maximum power density of 370 mW cm −2 in a LaBa 0.5 Sr 0.5 Fe 2 O 6-δ |SDC|LaBa 0.5 Sr 0.5 Fe 2 O 6-δ S-SOFC [194]. Figure 11 shows the electrochemical performance of the S-SOFC with a GdBaFe 2 O 5+δ | La 0.9 Sr 0.1 Ga 0.8 Mg 0.2 O 3-δ |GdBaFe 2 O 5+δ configuration when using dry H 2 , humidified syngas (61% H 2 , 24% CH 4 , 9.3% CO, 3.4% N 2 , 2.3% CO 2 , and 5 ppm H 2 S), and humidified CH 4 (3% H 2 O) as the fuels and the ambient air as the oxidant. The maximum peak power density of this cell at 1125 K was 1053, 868, and 197 mW cm −2 for the different fuels, respectively. The observed results indicate that this cell can efficiently operate with complex hydrocarbons fuels. This cell was also tested under a constant potential of 0.35 V with CH 4 as fuel at 973 K for 120 h to assess the carbon tolerance of the GdBaFe 2 O 5+δ anode and the stability of the cell (Figure 11d). No degradation of the cell performance was observed. The Raman spectrum (inset in Figure 11d) shows no peaks corresponding to the carbon deposited on the GdBaFe 2 O 5+δ anode surface, indicating that this material has a high coking tolerance. The peak at ca. 1300 cm −1 was assigned to FeOOH and was formed because a small part of exsolved iron nanoparticles reacted with water in humidified CH 4 .
The oxygen transport properties and the chemical stability of PrBaFe 2 O 5+δ (PBF)layered double perovskite were systematically studied in [198]. The oxygen permeation flux of 0.7 mm-thick samples and the oxygen-ion conductivity were 4.7 × 10 -1 mL min −1 cm −2 and 0.12 Scm −1 at 1173 K, respectively. The characteristic thickness estimated from the membrane and conductivity relaxation tests was~0.6 mm at 1173 K. The PBF oxide exhibited superior chemical stability in CO 2 -containing atmosphere.
Layered manganites of barium and REEs (for example, PrBaMn 2 O 5+δ ) have been considered as possible electrode materials both for A-SOFCs and S-SOFCs, as well as for SOECs cathodes [199][200][201]. The high thermal stability of Fe-doped PrBaMn 2-x Fe x O 6-δ perovskites both in oxidizing and reducing atmospheres and the moderate TEC values make these phases good candidates for electrochemical applications [200]. These phases may exchange relatively large amounts of oxygen with the atmosphere, which makes them promising oxygen storage materials as well.
(PBF)-layered double perovskite were systematically studied in [198]. The oxygen permeation flux of 0.7 mm-thick samples and the oxygen-ion conductivity were 4.7 × 10 -1 mL min −1 cm −2 and 0.12 Scm −1 at 1173 K, respectively. The characteristic thickness estimated from the membrane and conductivity relaxation tests was ~0.6 mm at 1173 K. The PBF oxide exhibited superior chemical stability in CO2-containing atmosphere.
Layered manganites of barium and REEs (for example, PrBaMn2O5+δ) have beenconsidered as possible electrode materials both for A-SOFCs and S-SOFCs, as well as for SOECs cathodes [199][200][201]. The high thermal stability of Fe-doped PrBaMn2-xFexO6-δ perovskites both in oxidizing and reducing atmospheres and the moderate TEC values make these phases good candidates for electrochemical applications [200]. These phases may exchange relatively large amounts of oxygen with the atmosphere, which makes them promising oxygen storage materials as well. Figure 11. Performance of the single cell with GdBaFe2O5+δ as its symmetrical electrodes for different fuels: (a) H2, (b) humidified syngas, and (c) humidified CH4. (d) Electrochemical stability test of the cell with humidified CH4 as a fuel during a 120 h operation. Inset: Raman spectrum of the anode surface area after stability test (reproduced with permission from [195]. Copyright 2021, Elsevier). Figure 11. Performance of the single cell with GdBaFe 2 O 5+δ as its symmetrical electrodes for different fuels: (a) H 2 , (b) humidified syngas, and (c) humidified CH 4 . (d) Electrochemical stability test of the cell with humidified CH 4 as a fuel during a 120 h operation. Inset: Raman spectrum of the anode surface area after stability test (reproduced with permission from [195]. Copyright 2021, Elsevier).
The Sr-deficient Sr 1.9 FeNb 0.9 Mo 0.1 O 6-δ double perovskite was prepared via a solid state reaction method and tested as the electrode in S-SOFCs [202]. The electrocatalytic activity of Sr 1.9 FeNb 0.9 Mo 0.1 O 6-δ was greatly improved by the impregnation of the solution of Pd(NO 3 ) 2 to form Pd-Sr 1.9 FeNb 0.9 Mo 0.1 O 6-δ composite electrodes. The single cell with such symmetrical electrodes after two-time impregnation achieved the peak power densities of 935.4, 196.5, and 11.2 mW cm −2 at 1123 K in dry H 2 , humidified CH 4 , and 17CH 4 -83CO 2 mixed gas, respectively, revealing superior performance in different fuels.
In [90], it was shown that Sr 2 Co 1−x Nb x FeO 5+δ (x = 0.0-0.2) double perovskites have good structural stability and chemical compatibility with La 0.9 Sr 0.1 Ga 0.8 Mg 0.2 O 3-δ and Ce 0.8 Sm 0.2 O 1.9 electrolytes. The ASR of the Sr 2 Co 1.9 Nb 0.1 FeO 5+δ cathode was 0.081 Ω cm 2 at 973 K on the LSGM electrolyte. This cathode showed good electrocatalytic activity for ORR, functional stability, and high electrical conductivity.
The possibility of using Sr 2 Sc 0.1 Nb 0.1 Co 1.5 Fe 0.3 O 6-2δ thin films as cathodes for IT-SOFCs was tested in [203]. It was found that the film grown along the [110] direction on the YSZ substrate demonstrated lower polarization resistances and smaller activation energy than the film grown along the [100] direction on the SDC/YSZ substrate, indicating better ORR activity. It was also found that the lower Sr-enrichment and higher cobalt-ion oxidation states were beneficial for the ORR.
The lowest polarization resistance of 0.39 Ω cm 2 at 1073 K was found for materials with x = 0.05.

Short Resume
Layered oxygen-deficient double perovskites (primarily cobaltites and their derivatives) are promising cathode materials for IT-SOFCs due to their high electrocatalytic activity in ORR, stability at elevated temperatures and chemical and thermomechanical compatibility with solid electrolytes.
Despite numerous advantages, LODPs have a number of drawbacks in terms of their applications in SOFCs. The literature analyses performed above shows that the main problems are their degradation in CO 2 -containing atmospheres and relatively large TEC values, as well as chemical expansion at high temperatures due to the loss of weakly-bonded oxygen.
These disadvantages can be eliminated or reduced by tuning the chemical composition of the LODPs or by producing their composites containing different solid electrolytes as a second phase. The electrochemical performance of LODPs can be essentially improved both by the substitution of cations in their A-or/and B-sublattices or by the creation of small cation deficiencies in the A-sublattice ( Figure 12). The TEC values and chemical expansion of the LODPs may be reduced by the formation of high-entropy oxides (HEOs) on their base, in which A-or/and B-positions are shared by at least five REEs (as well as alkaline-earth elements) and transition metals, respectively, in equal or near-equal atomic ratios. Such HEOs should be more stable and possess lower polarization resistances compared when with other cathodes based on LODPs. The addition of solid electrolytes to LODPs lowers their TECs and makes them more chemically and thermomechanically compatible with electrolytes and can also improve the electrochemical performanceof composite cathodes due to enlarging the zones of the ORRs. The creation of a hierarchical porous microstructure of cathodes also enlarges the areas of the ORRs and improves their electrochemical and electrocatalytical performance.
LODPs based on light REEs have small oxygen deficiencies (large amounts of weaklybonded oxygen), high values of the Seebeck coefficient, and electrical conductivity, and they also contain transition metal ions in different oxidation states. For these reasons they may be used as high-temperature thermoelectrics, oxygen storage materials, or photocatalysts for the oxidation of organic substances.

Conclusions
Layered oxygen-deficient perovskites (LODPs) are considered promising candidates for use as cathodes in IT-SOFC applications. In this review, we shortly summarized the available literature data concerning their crystal structure, thermal, and electrotransport and functional, especially electrochemical, properties. The phase transitions of different natures (structural, electric, and magnetic), which take place in LODPs due to the variations of temperature and their chemical composition, were also discussed. The electrochemical performance of materials belonging to different groups of LODPs (cobaltites, ferrites, etc.) in single cells based on both oxygen-ion-and proton-conducting solid electrolytes was found to be quite high for applied purposes. The main focus was on various chemical engineering approaches to improve the electrochemical activity of these materials (creation of cationic deficiencies, doping on different sites, modification by noble metals and solid electrolytes nanoparticles, etc.). It was demonstrated that some LODPs can effectively operate as electrodes of symmetrical SOFCs fueled with hydrogen, methane, or complex hydrocarbons. The other possible areas of usage of these complex oxides (hightemperature thermoelectrics, oxygen storage materials, photocatalysts, etc.) were alsofinally depicted.
Although this work overviews the last trends in LODPs, a number of recent publications fell within the reviewing procedure. In our opinion, these works [205][206][207][208][209][210][211] should be mentioned with no detailed analysis.

Conclusions
Layered oxygen-deficient perovskites (LODPs) are considered promising candidates for use as cathodes in IT-SOFC applications. In this review, we shortly summarized the available literature data concerning their crystal structure, thermal, and electrotransport and functional, especially electrochemical, properties. The phase transitions of different natures (structural, electric, and magnetic), which take place in LODPs due to the variations of temperature and their chemical composition, were also discussed. The electrochemical performance of materials belonging to different groups of LODPs (cobaltites, ferrites, etc.) in single cells based on both oxygen-ion-and proton-conducting solid electrolytes was found to be quite high for applied purposes. The main focus was on various chemical engineering approaches to improve the electrochemical activity of these materials (creation of cationic deficiencies, doping on different sites, modification by noble metals and solid electrolytes nanoparticles, etc.). It was demonstrated that some LODPs can effectively operate as electrodes of symmetrical SOFCs fueled with hydrogen, methane, or complex hydrocarbons. The other possible areas of usage of these complex oxides (high-temperature thermoelectrics, oxygen storage materials, photocatalysts, etc.) were alsofinally depicted.
Although this work overviews the last trends in LODPs, a number of recent publications fell within the reviewing procedure. In our opinion, these works [205][206][207][208][209][210][211] should be mentioned with no detailed analysis.

Conflicts of Interest:
The authors declare no conflict of interest.